Zusammenfassung
Mit Kristallographie bezeichnet man die Wissenschaft, die sich mit dem räumlich periodisch geordneten Zustand der Materie befaßt. Sie behandelt die mathematischen, physikalischen und chemischen Gesetzmäßigkeiten der transiationssymmetrischen Ordnung von Atomen und Molekülen in Kristallen. Die Kristallographie bildet somit eine Klammer zwischen den verschiedenen Disziplinen der Wissenschaft von der kondensierten Materie, wie z. B. Festkörperphysik, Festkörperchemie, Mineralogie, Werkstoffwissenschaften, und über die mathematischen Gesetzmäßigkeiten der Symmetrietheorie (Gruppentheorie) hat sie einen engen Bezug zur Mathematik.
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Literatur
Astbury WT, Yardley K (1924) Tabulated data for the examination of the 230 space groups by homogeneous X-rays. Philos Trans R Soc London A224:221–257.
Barlow W (1883) Probable nature of the internai symmetry of crystals. Nature (London) 29:186–188, 205-207.
Bedzyk M, Materlik G (1985) X-Ray standing wave analysis for bromine chemisorbed on germanium. Surf Sci 152:10–16.
Bernai JD (1926) On the interpretation of X-ray singlecrystai rotation photographs. Proc R Soc London A 113:117–170.
Bijvoet JM, Peerdeman AF, Van Bommei AJ (1951) Determination of the absolute configuration of optically active compounds by means of X-rays. Nature (London) 168:271.
Bonse U, Hart M (1965) An X-ray Interferometer. Appl Phys Letters 6:155–156.
Borrmann G (1950) Die Absorption von Röntgenstrahlen im Fall der Interferenz. Z Phys 127:297–323.
Bragg WH, Bragg WL (1913) The reflection of X-rays by crystals. Proc R Soc London A 88:428–438.
Bragg WL (1912) The specular reflexion of X-rays. Nature (London) 90:410.
Bragg WL (1913a) The diffraction of short electromagnetic waves by a crystal. Proc Cambridge Philos Soc 17:43–57.
Bragg WL (1913b) The structure of some crystals as indicated by their diffraction of X-rays. Proc R Soc London A 89:248–277.
Buerger MJ (1935) The application of plane groups to the interpretation of Weissenberg photographs. Z Kristallogr 88:356–380.
Buras B, Gerward L (1992) Energy-dispersive techniques for X-rays. In: Wilson AJC (ed) International tables for crystallography, vol C. Kluwer Academic Publishers, Dordrecht Boston London, pp 84–87.
Cochran W (1955) Relations between the phases of structure factors. Acta Cryst 8:473–478.
Coster D, Knol KS, Prins JA (1930) Unterschiede in der Intensität der Röntgenstrahlenreflexion an den beiden 111-Flächen der Zinkblende. Phys 63:345–369.
Cromer DT, Liberman DA (1983) Calculations of anomalous scattering factors at arbitrary wavelength. J Appl Cryst 16:437.
Cruickshank DWJ, Juretschke HJ, Kato N (1992) (eds) P. P. Ewald and his dynamical theory of X-ray diffraction. Oxford University Press, New York.
Dam B, Janner A, Donnay JDH (1985) Incommensurate morphology of calaverite crystals. Phys Rev Lett 55:2301–2304.
Darwin CG (1914) The theory of X-ray reflection. Philos Mag 27:315–333, 675-690.
Debye P (1914) Interferenz von Röntgenstrahlen und Wärmebewegung. Ann Phys (Leipzig) 43:49–95.
Debye P, Scherrer P (1916) Interferenz an regellos orientierten Teilchen im Röntgenlicht. Phys Z 17:277–283.
Dmitrienko VE (1983) Forbidden reflections due to anisotropic X-ray susceptibility of crystals. Acta Cryst A 39:29–35.
Donnay JDH (1935) Morphologie des cristaux de calaverite. Ann Soc Geol Belg B55:222–230.
Eichhorn K, Kek S, Schmidt C, Kirfel A, Bismayer U (1994) Redetermination of the crystal structure of sanidine: a synchroton radiation study. (to be published).
Eisenberger P, Marra WC (1981) X-ray diffraction study of the Ge(001) reconstructed surface. Phys Rev Letters 46:1081–1084.
Ewald PP (1917) Zur Begründung der Kristalloptik. Ann Phys (Leipzig) 54:519–597.
Ewald PP (ed) (1962) Fifty years of X-ray diffraction. NVA Oosthoek’s Uitgeversmaatschapij, Utrecht.
Feidenhans’l R (1989) Surface structure determination by X-ray diffraction. Surf Sci Rep 10:105–188.
Friedel G (1913) Sur les symétries cristallines que peut révéler la diffraction des rayons Röntgen. Compt Rend Acad Sci 157:1533–1536.
Guinier A (1937) Rayons-X-dispositif permettant d’obtenir des diagrammes de diffraction de poudres cristalins trés intenses avec un rayonnement monochromatique. Compt Rend Acad Sci 204:1115–1116.
Hahn T (1992) International tables for crystallography, vol A: Space group symmetry. Reidel, Dordrecht.
Harker D (1936) The application of the three-dimensional Patterson method. J Chem Phys 4:381–390.
Hart M (1981) Bragg angle measurement and mapping. J Cryst Growth 55:409–427.
Helliwell JR (1992) Macromolecular crystallography with synchrotron radiation. Cambridge University Press, Cambridge.
Henry NFM, Lonsdale K (eds) (1952) International tables for X-ray crystallography, vol 1 Kynoch, Birmingham.
Hermann CH (Hrsg) (1935) Internationale Tabellen zur Bestimmung von Kristallstmkturen, Bd 1. Borntraeger, Berlin.
Höni H (1933) Atomfaktor für Röntgenstrahlen ais Problem der Dispersionstheorie (K-Schale). Ann Phys (Leipzig) 18:625–657.
Hummer K, Schwegle W, Weckert E (1992) Experimental determination of reflection phases by three-beam diffraction and its application. Acta Phys Pol A 82:83–102.
Jagodzinski H, Frey F (1993) Disorder diffuse scattering of X-ray and neutrons. In: Shmueli U (ed) International tables for crystallography, vol B. Kluwer Academic Publishers, Dordrecht Boston London, pp 392–434.
Janssen T, Janner A, Looijenga-Vos A, Wolff PM (1992) Incommensurate and commensurate modulated structures. In: Wilson AJC (ed) International tables for crystallography, vol C. Kluwer Academic Publishers, Dordrecht Boston London, pp 797–845.
Laval J (1938) Sur la diffusion des rayons X par un cristal. C R Acad Sci 207:169–170.
Lima-de-Faria J (1990) Historical atlas of crystallography. Kluwer Academic Publishers, Dordrecht Boston London.
Luger P (1993) Crystal structure analysis at normal and low temperature conditions. Cryst Res Tech 28:767–794.
Masien EN (1992) X-ray Absorption. In: Wilson AJC (ed) International tables for crystallography, vol C. Kluwer Academic Publishers, Dordrecht Boston London, pp 520–530.
Maslen EN, Fox AG, O’Keefe MA (1992) Interpretation of diffracted intensities. X-ray scattering. In: Wilson AJC (ed) International tables for crystallography, vol C. Kluwer Academic Publishers, Dordrecht Boston London, pp 476–512.
Monaco HL (1992) Experimental methods in X-ray crystallography. In; Giocavazzo C (ed) Fundamentals of crystallography. Oxford University Press, New York, pp 229–318.
Niggli P (1919) Geometrische Kristallographie des Diskontinuums. Borntraeger, Leipzig.
Patterson AL (1934) A Fourier series method for the determination of the components of interatomic distances in crystals. Phys Rev 46:372–376.
Pinsker ZG (1978) Dynamical scattering of X-ray in crystals. In: Cardona M, Fuide P, Quesser JH (eds) Springer Series in Solid-State Sciences 3. Springer, Berlin Heidelberg New York.
Ramachandran GN, Wooster WA (1949) Determination of elastic constants from diffuse reflexion of X-rays. Nature (London) 164:839–840.
Rietveld HM (1969) A profile finement method for nuclear and magnetic structures. J Appl Cryst 2:65–71.
Robinson IK (1991) Surface crystallography; In: Brown GS, Moncton DE (eds) Handbook on synchrotron radiation. North-Holland, Amsterdam Oxford New York Tokyo, pp 221–266.
Robinson W, Sheldrick GM (1988) In: Isaacs NW, Taylor RM (eds) Crystallographic computing 4. Oxford University Press, Oxford, pp 366–377.
Schwarz LH, Cohen JB (1987) Diffraction from materials. Springer, Berlin Heidelberg New York Tokyo.
Seemann H (1919) Eine fokussierende röntgenspektroskopische Anordnung für Kristallpulver. Ann Phys (Leipzig): 59:455–464.
Shechtman D, Blech I, Gratias D, Cahn JW (1984) Metallic phase with long-range orientational order and no translational symmetry. Phys Rev Lett 53:1951–1953.
Smith GFH (1903) Über das bemerkenswerte Problem der Entwicklung der Krystaliformen des Caiaverit. Z Kristalogr 37:209–234.
Stern E A (1974) Theory of the extended X-ray absorption fine structure. Phys Rev 10:3027–3028.
Tanner BK (1976) X-ray diffraction topography. Pergamon, Oxford New York Toronto Sydney Paris Frankfurt.
Templeton DM, Tempieton LK (1985) Tensor X-ray optical properties of the bromate ion. Acta Cryst A41:133–142.
Walier I (1923) Zur Frage der Einwirkung der Wärmebewegung auf die Interfeenz von Röntgenstrahlen. Z Phys 17:398–408.
Weissenberg K (1924) Ein neues Röntgengoniometer. Z Phys 23:229–239.
West J (1930) A quantitative X-ray analysis of the structure of potassium dihydrogen phosphate (KH2PO4). Z Kristaliogr 74:306–332.
Willis BTM (1993) Thermal diffuse scattering of X-rays and neutrons. In: Shmueli U (ed) International tables for crystalography, vol B. Kluwer Academic Publishers, Dordrecht Boston London, pp 384–392.
Wilson AJC (ed) (1992) International tables for crystallography, vol C. Mathematical, physical and chemical tables. Kluwer Academic Publishers, Dordrecht Boston London.
Zachariasen WH (1929) The crystal structure of sodium chlorate. Z Kristallogr 71:517–529.
Zachariasen WH (1963) The secondary extinction correction, Acta Cryst A16: 1139–1144.
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Hümmer, K. (1995). Röntgenstrahlen in der Kristallographie. In: Heuck, F.H.W., Macherauch, E. (eds) Forschung mit Röntgenstrahlen. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-78841-3_27
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